JP5605350B2 - Switching power supply control circuit - Google Patents

Description

  The present invention relates to a control circuit for a switching power supply.

  For example, in a switching power supply that supplies a power supply voltage to a switching amplifier, a low voltage detection circuit is provided on the secondary winding side of the transformer, and when the voltage of the secondary winding of the transformer is detected to be low, While stopping the operation, the switching power supply shifts from the normal operation state to the standby state. When the switching power supply shifts to the standby state, the following problems occur. Since the power supply voltage output from the switching power supply is small in the standby state, the charging voltage of the smoothing capacitor on the primary winding side of the transformer is not used immediately for the output of the power supply voltage in the switching power supply, and there is a relatively long period of time. Remains. When the operation of the switching amplifier is stopped when a low voltage is detected, the load becomes lighter, so the voltage of the secondary winding of the transformer rises and the input AC power supply voltage is still low. Nevertheless, it is once determined that the voltage is not low. Therefore, the operation of the switching amplifier is started. Then, the load becomes heavier, the voltage of the secondary winding of the transformer decreases, and it is determined that the voltage is low. In this way, until the charging voltage of the smoothing capacitor is completely consumed, a process for detecting the low voltage and stopping the operation of the switching amplifier, and a process for starting the operation of the switching amplifier without detecting the low voltage Is repeated over a long period of time, and as a result, there is a problem that noise is generated from the speaker.

JP-A-9-16274

  The present invention has been made to solve the above-described conventional problems, and an object of the present invention is to prevent a state in which a low voltage is detected and a state in which a low voltage is not detected from being repeated over a long period of time. It is to provide a control circuit.

A control circuit according to a preferred embodiment of the present invention controls a switching amplifier included in the audio device to operate or stop in synchronization with a normal operation state and a standby state of the audio device, and the normal state of the audio device A control circuit for controlling a switching power supply to a normal operation state or a standby state in conjunction with an operation state and a standby state , wherein the switching power supply is supplied with a power supply voltage and switched according to a control signal from a switching control unit A switching element that performs an operation; a switching control unit that supplies a control signal for switching the switching element to the switching element; and a feedback signal that is supplied to the switching control unit in a normal operation state of the switching power supply. not, the switching In the standby state of the source, the feedback signal corresponding to the output voltage from the switching element and a feedback control section for supplying to the switching control unit, the switching control unit, when the feedback signal is not supplied, the When the switching element is always switched and the feedback signal is supplied, the switching element is intermittently switched according to the feedback signal. The control circuit has a low output voltage of the switching power supply. A low voltage detection unit that detects that the voltage is a voltage, and supplies a feedback signal to the switching control unit when the output voltage of the switching power supply is detected to be a low voltage in a normal operation state of the audio device. The feedback control unit is controlled so that the switching power supply is maintained in a normal operation state. And parts, in the normal operation state of the audio device, when the output voltage of the switching power supply is detected to be at a low voltage, the stop control for stopping the drive signal output operation of the switching amplifier of the driver from the first node A stop control signal output unit for outputting a signal .

  When it is detected that the output voltage of the switching power supply is a low voltage, the control circuit controls the feedback control unit so as not to supply the feedback signal to the switching control unit, and maintains the switching power supply in a normal operation state. Therefore, the transition to the standby state is prevented. In the normal operation state, a power supply voltage higher than that in the standby state is output, so that the capacitor charging voltage is quickly consumed. Therefore, it is possible to prevent the state in which the low voltage is detected and the state in which the low voltage is not detected from being repeated over a long period.

  In a preferred embodiment, the feedback control unit receives a regulator element that generates a current corresponding to an output voltage from the switch element and a current flowing through the regulator element, and outputs an optical signal as the feedback signal. A light-emitting element; a light-receiving element that receives an optical signal from the light-emitting element and causes a current as the feedback signal to flow to the switching control unit; and a state switch element that switches whether or not to flow a current to the regulator element. The control unit controls the state switch element so that no current flows through the regulator element when it is detected that the output voltage of the switching power supply is a low voltage.

In a preferred embodiment, the protect signal for stopping the operation of the switching control unit of the switching power supply before Symbol first node is supplied, a current flows in response to the protect signal, a second light emitting outputting light signals OFF when an element, a second light receiving element that stops the operation of the switching control unit in response to an optical signal from the second light emitting element, and the output voltage of the switching power supply are low are detected. And a transistor for controlling the current to flow through the second light emitting element by opening the path through which the current flows through the second light emitting element.

  It is possible to provide a switching power supply control circuit that prevents a state in which a low voltage is detected and a state in which a low voltage is not detected from being repeated over a long period.

1 is a block diagram illustrating an audio device according to a preferred embodiment of the present invention. It is a circuit diagram which shows a switching amplifier. It is a circuit diagram which shows a switching power supply. It is a circuit diagram which shows a control circuit. 3 is a timing chart showing the operation of the control circuit 3. 3 is a timing chart showing the operation of the control circuit 3. 3 is a timing chart showing the operation of the control circuit 3.

  Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings. However, the present invention is not limited to these embodiments. As shown in FIG. 1, the audio apparatus according to the present embodiment includes a switching amplifier 1, a switching power supply 2, and a control circuit 3. The switching amplifier 1 amplifies an input signal (audio signal) to be input, and supplies the amplified audio signal to a speaker (load) connected to the outside. The switching power supply 2 generates a DC power supply voltage from the input AC power supply voltage and supplies it to the switching amplifier 1. The control circuit 3 is a circuit that controls operations of the switching amplifier 1 and the switching power supply 2.

[Switching amplifier]
FIG. 2 is a circuit diagram showing the switching amplifier 1. The switching amplifier 1 generally includes a driver Q1, switching elements Q2 and Q3, and an LPF (low-pass filter, coil L1, capacitor C1). The driver Q1 generates drive signals DRV1 and DRV2 that are, for example, pulse width modulation signals for on / off control of the switch elements Q2 and Q3 from an input signal (for example, an audio signal) input to the signal input terminal SIN. The driver Q1 supplies the high-side drive signal DRV1 from the output terminal HO to the switch element Q2, and supplies the low-side drive signal DRV2 from the output terminal LO to the switch element Q3. The drive signals DRV1 and DRV2 have two values, a high level and a low level. For example, when one is at a high level, the other is at a low level.

  For example, MOSFETs are used as the switch elements Q2 and Q3. The MOSFET Q2 has a gate connected to the output terminal HO of the driver Q1, a source connected to the drain of the MOSFET Q3, the terminals VS and LPF of the driver Q1, and a drain connected to the node X4 so that the positive power supply voltage + B is Supplied. The node X4 is connected to the node X4 in FIG. The MOSFET Q3 has a gate connected to the output terminal LO of the driver Q1, a drain connected to the source of the MOSFET Q2, the terminals VS and LPF of the driver Q1, and a source connected to the node X5 so that the negative power supply voltage −B Is supplied. The node X5 is connected to the node X5 in FIG. MOSFETs Q2 and Q3 are constantly supplied with power supply voltages + B and -B in both the normal operation state and the standby state of the audio apparatus.

  For example, the MOSFET Q2 is turned on when the drive signal DRV1 is at a high level and turned off when the drive signal DRV1 is at a low level. For example, the MOSFET Q3 is turned on when the drive signal DRV2 is at a high level and turned off when the drive signal DRV2 is at a low level. When one of MOSFETs Q2 and Q3 is on, the other is off. When the MOSFET Q2 is on, a positive power supply voltage + B is supplied to the LPF, and when the MOSFET Q3 is on, a negative power supply voltage -B is supplied to the LPF.

  The LPF removes high frequency components from the voltages supplied from the MOSFETs Q2 and Q3, and supplies an amplified audio signal to a speaker as a load.

  The switching amplifier 1 further includes power control units 1A and 1B. The driver Q1 has power input terminals VAA and VSS, and is turned on when the power supply voltage VAA is input to the power input terminal VAA and the power supply voltage VSS is input to the power input terminal VSS. For example, a process of generating and outputting a drive signal is executed, but if the power supply voltage is not supplied, the operation is performed in an off state. The power supply control unit 1A switches between a state in which the power supply voltage VAA is supplied to the power supply input terminal VAA of the driver Q1 and a state in which the power supply voltage VAA is not supplied in accordance with a control signal from the control circuit 3. That is, for example, when the audio device is in a standby state, when performing a protect operation, when a low voltage is detected, the power supply voltage VAA is not supplied to the power input terminal VAA of the driver Q1, and the driver Q1 is in a normal operation state. The power supply voltage VAA is supplied to the power input terminal VAA. Similarly, the power control unit 1B switches between a state in which the power supply voltage VSS is supplied to the power input terminal VSS of the driver Q1 and a state in which the power supply voltage VSS is not supplied in accordance with a control signal from the control circuit 3. That is, when the audio device is in the standby state, when the protect operation is executed, when the low voltage is detected, the power supply voltage VSS is not supplied to the power supply input terminal VSS of the driver Q1, and the power supply of the driver Q1 is in the normal operation state The power supply voltage VSS is supplied to the input terminal VSS. Therefore, in the standby state, the power supply voltages VAA and VSS are not supplied to the driver Q1, and the operation of the switching amplifier 1 can be stopped, so that the power consumption of the audio device can be reduced. In addition, when the protect operation is performed, when the low voltage is detected, the power supply voltages VAA and VSS are not supplied to the driver Q1, and the operation of the switching amplifier 1 can be stopped, so that damage or malfunction can be prevented.

  The power supply control unit 1A includes resistors R1 to R3, capacitors C2 and C3, a transistor Q4, a diode D1, and a three-terminal regulator (voltage stabilization unit) Q5. The base of the transistor Q4 is connected to the node X1 via the resistor R3, the emitter is connected to the node X4 via the resistor R1, the power supply voltage + B is supplied, and the collector is connected to the input terminal I of the three-terminal regulator Q5. ing. The output terminal O of the three-terminal regulator is connected to the power input terminal VAA of the driver Q1. The node X1 is connected to the node X1 in FIG. 4 and receives a control signal from the control circuit 3. Since the transistor Q4 is turned on when a low level signal is supplied from the node X1 to the base, the transistor Q4 supplies the power supply voltage + B to the three-terminal regulator Q5. At this time, the three-terminal regulator Q5 supplies the power supply voltage VAA to the power input terminal VAA of the driver Q1. On the other hand, the transistor Q4 is turned off when the low-level signal is not supplied to the base from the node X1, and thus the power supply voltage + B is not supplied to the three-terminal regulator Q5. At this time, the three-terminal regulator Q5 does not supply the power supply voltage VAA to the power supply input terminal VAA of the driver Q1.

  The power supply control unit 1B includes resistors R4 to R6, capacitors C4 and C5, a transistor Q6, a diode D2, and a three-terminal regulator (voltage stabilization unit) Q7. The base of the transistor Q6 is connected to the node X2 via the resistor R6, the emitter is connected to the node X5 via the resistor R4, the power supply voltage -B is supplied, and the collector is connected to the input terminal I of the three-terminal regulator Q7. Has been. The output terminal O of the three-terminal regulator is connected to the power input terminal VSS of the driver Q1. The node X2 is connected to the node X2 in FIG. Since the transistor Q6 is turned on when a high level signal is supplied from the node X2 to the base, the transistor Q6 supplies the power supply voltage -B to the three-terminal regulator Q7. At this time, the three-terminal regulator Q7 supplies the power supply voltage VSS to the power supply input terminal VSS of the driver Q1. On the other hand, the transistor Q6 is turned off when the high-level signal is not supplied to the base from the node X2, so that the power supply voltage -B is not supplied to the three-terminal regulator Q7. At this time, the three-terminal regulator Q7 does not supply the power supply voltage VSS to the power supply input terminal VSS of the driver Q1.

  As shown in FIG. 3, the switching amplifier 1 further includes a power supply control unit 1C. The power supply control unit 1C switches between a state in which the power supply voltage VB is supplied to the power supply input terminal VCC of the driver Q1 and a state in which the power supply voltage VB is not supplied in accordance with a control signal from the control circuit 3. That is, when the audio device is in a standby state, when performing a protect operation, when a low voltage is detected, the power supply voltage VB is not supplied to the power supply input terminal VCC of the driver Q1, and the power supply of the driver Q1 is in a normal operation state. The power supply voltage VB is supplied to the input terminal VCC. The driver Q1 generates and outputs drive signals DRV1 and DRV2 when the power supply voltage VCC is supplied to the power supply input terminal VCC, and does not output the drive signals DRV1 and DRV2 when the power supply voltage is not supplied.

  The power control unit 1C includes a resistor R13, diodes D7 and D8, transistors Q13 and Q14, a capacitor C9, and a three-terminal regulator (voltage stabilization unit) Q15. The base of the transistor Q13 is connected to the collector of the transistor Q14, the emitter is connected to the secondary winding of the transformer T via the diode D7 and the resistor R13, the power supply voltage is supplied, and the collector is input to the three-terminal regulator Q15. Connected to terminal I. Transistor Q14 has a collector connected to the base of transistor Q13, an emitter connected to node X5, and a base connected to node X3. The node X3 is connected to the node X3 in FIG. 4 and supplied with a control signal from the control circuit 3.

  The output terminal O of the three-terminal regulator Q15 is connected to the node X6. The node X6 is connected to the node X6 in FIG. 2 (that is, the power input terminal VCC of the driver Q1). When a high level signal is supplied from the node X3 to the base of the transistor Q14, the transistor Q14 is turned on and the transistor Q13 is turned on. At this time, since the voltage from the secondary winding of the transformer T is supplied to the three-terminal regulator Q15, the power supply voltage VB is supplied to the power supply input terminal VCC of the driver Q1. On the other hand, when a high level signal is not supplied from the node X3 to the base of the transistor Q14, the transistor Q14 is turned off and the transistor Q13 is turned off. At this time, since the voltage from the secondary winding of the transformer T is not supplied, the three-terminal regulator Q15 does not supply the power supply voltage VB to the power supply input terminal VCC of the driver Q1.

[Function and effect of the switching amplifier 1]
When the supply of the power supply voltage to the switching amplifier 1 is cut off in the standby state, a relay switch is required to cut off the path for supplying the power supply voltages + B and -B to the drains of the MOSFETs Q2 and Q3. This is because the MOSFETs Q2 and Q3 are connected to the speaker, and it is necessary to flow a large current based on the power supply voltages + B and -B. That is, if a transistor is used as a switch for cutting off the power supply voltages + B and -B, the withstand current of the transistor may be exceeded due to a large current, and the transistor may be damaged. Therefore, the transistor cannot be used. Therefore, it is necessary to use a relay switch. However, the relay switch has a problem that the cost is large and large, and noise is generated when the switch is turned on and off. This embodiment is characterized in that the power supply voltage is cut off. Specifically, the power supply voltages VAA, VSS and VB supplied to the driver Q1 are cut off instead of the MOSFET. When the power supply voltages VAA and VSS or the power supply voltage VB are not supplied, the driver Q1 does not generate and output the drive signals DRV1 and DRV2 (the drive signals DRV1 and DRV2 are both at a low level). Accordingly, the MOSFETs Q2 and Q3 do not perform the switching operation (the MOSFETs Q2 and Q3 are both turned off), and the operation of the switching amplifier is performed in the same manner as when the power supply voltages + B and -B are not supplied to the MOSFETs Q2 and Q3. Can be stopped. Since a large current does not flow to supply the power supply voltages VAA, VSS, and VB to the driver Q1, a transistor can be used instead of the relay switch. By using a transistor, effects such as small size, low cost, and reduction of noise during switching can be obtained.

  Furthermore, when switching the supply / non-supply of the power supply voltages + B and -B to the MOSFETs Q2 and Q3 using a relay switch, when switching from the standby state to the normal operation state, the switching operations of the MOSFETs Q2 and Q3 are stabilized. Takes time. However, according to the present embodiment, since the power supply voltages + B and -B supplied to the MOSFETs Q2 and Q3 are not cut off and are always supplied even in the standby state, such a problem can be solved. Further, since no relay switch is used, it is possible to prevent noise from being generated due to the ON / OFF operation of the relay switch.

[Switching power supply]
FIG. 3 is a circuit diagram mainly showing the switching power supply 2. The switching power supply 2 includes full-wave rectifier circuits D3 and D6, smoothing capacitors C101 and C102, switch elements Q8 and Q9, resistors R7 to R13, diodes D4, D5, and D7, capacitors C7, C8, and C10, It has a transformer T and a switching control circuit Q12. The full-wave rectifier circuit D3 performs full-wave rectification on the input AC power supply voltage, and the smoothing capacitors C101 and C102 smooth the DC voltage from the full-wave rectifier circuit D3 and supplies the DC voltage to the switch elements Q8 and Q9.

  For example, MOSFETs are used as the switch elements Q8 and Q9. The MOSFET Q8 has a source connected to the drain of the MOSFET Q9, is connected to the primary winding of the transformer T via the capacitor C6, and a gate is connected to the high-side control terminal HVG of the switching control circuit Q12 via the resistor R9. The drain is connected to the positive output terminal of the full-wave rectifier circuit D3, and a positive DC voltage (high level signal) is supplied. MOSFET Q9 has its drain connected to the source of MOSFET Q8, connected to the primary winding of transformer T via capacitor C6, and its gate connected to low side control terminal LVG of switching control circuit Q12 via resistor R10. The source is connected to the ground potential (low level signal).

  The switching control circuit Q12 controls the on / off operation of the MOSFETs Q8 and Q9. When one of the MOSFETs Q8 and Q9 is on, the other is off. The MOSFET Q8 is turned on when a high level signal is supplied to the gate from the control terminal HVG of the switching control circuit Q12, and supplies a positive DC voltage to the primary winding of the transformer T. The MOSFET Q9 is turned on when a high level signal is supplied to the gate from the control terminal LVG of the switching control circuit Q12, and supplies the ground potential to the primary winding of the transformer T.

  The transformer T steps down the voltage supplied to the primary winding and outputs it to the secondary winding. The voltage induced in the secondary winding of the transformer T is full-wave rectified by a full-wave rectifier circuit D6. The full-wave rectifier circuit D6 outputs a positive power supply voltage + B from the positive output terminal to the node X4, and outputs a negative power supply voltage −B from the negative output terminal to the node X5. The voltage induced in the secondary winding of the transformer T is rectified and smoothed by the resistor R13, the diode D7, and the capacitor C10, and output to the node X6 as the power supply voltage VB via the power supply control unit 1C. The voltage induced in the tertiary winding of the transformer T is rectified and smoothed by the diodes D4 and D5 and the capacitor C7 and supplied to the power input terminal VCC of the switching control circuit Q12.

  The switching power supply 2 has a feedback control unit 2A. The feedback control unit 2A forms a negative feedback circuit for the switching power supply 2 to give a negative feedback signal, or does not form a negative feedback path and switches between giving no negative feedback signal. The feedback control unit 2A gives a negative feedback signal to the switching power supply 2 in the standby state, and does not give a negative feedback signal to the switching power supply 2 in the normal operation state.

  The feedback control unit 2A includes transistors Q17 and Q18, resistors R19 to R27, capacitors C11 to C14, diodes D10 and D11, photocouplers (LEDQ19 and phototransistor Q10), and a shunt regulator SR. The resistors R20, R21, and R22 are supplied with a voltage induced in the secondary winding of the transformer T via the resistor R26 and the diode D10, and divide the power supply voltage and supply it as a reference voltage to the REF terminal of the shunt regulator SR. .

  The shunt regulator SR changes the current flowing from the cathode to the anode according to the difference between the voltage input to the REF terminal and the internal reference voltage. That is, when the voltage input to the REF terminal is large, the cathode-anode current increases, and when the voltage input to the REF terminal is small, the cathode-anode current decreases. The shunt regulator SR has a REF terminal connected to a connection point between the resistors R21 and R22, an anode connected to the ground potential, and a cathode connected to the emitter of the transistor Q18.

  The LED Q19 flows in accordance with the cathode-anode current flowing through the shunt regulator SR, generates an optical signal corresponding to the current value, and transmits the optical signal to the phototransistor Q10. Since the cathode-anode current flowing through the shunt regulator SR is based on the voltage of the secondary winding of the transformer T, this optical signal also varies depending on the voltage of the secondary winding of the transformer T, and this optical signal is a negative feedback signal. It corresponds to. The LED Q19 has a cathode connected to the collector of the transistor Q18 and an anode connected to the power supply voltage line via the resistor R25.

  The transistors Q17 and Q18 switch whether or not to supply a negative feedback signal to the switching control circuit Q12 according to the control signal from the control circuit 3. The transistor Q17 has a base connected to the node X9, an emitter connected to the ground potential, and a collector connected to the power supply voltage line via the resistor R19. The node X9 is connected to the node X9 in FIG. The transistor Q18 has a base connected to the collector of the transistor Q17, an emitter connected to the cathode of the shunt regulator SR, and a collector connected to the cathode of the LED Q19.

  The operation will be described. For example, in a normal operation state, a high level signal is supplied from the node X9, the transistor Q17 is turned on, and the transistor Q18 is turned off. When the transistor Q18 is turned off, the LED Q19 is opened to the shunt regulator SR, so that no current flows. As a result, the negative feedback signal is not supplied to the switching control circuit Q12. Specifically, in FIG. 3, since the collector current does not flow through the phototransistor Q10, no current flows through the COMP terminal of the switching control circuit Q12. Therefore, the switching control circuit 12 always outputs a signal that repeats the high level and the low level from the control terminals HVG and LVG, and alternately turns on and off the MOSFETs Q8 and Q9. Therefore, in a normal operation state, a high power supply voltage is output without executing negative feedback.

  On the other hand, in the standby state, for example, a high level signal is not supplied from the node X9, the transistor Q17 is turned off, and the transistor Q18 is turned on. When the transistor Q18 is turned on, the LED Q19 is connected to the shunt regulator SR, so that a current flows. Since this current changes in accordance with the cathode-anode current of the shunt regulator SR, it changes in accordance with the voltage induced in the secondary winding of the transformer T. The LED Q19 supplies an optical signal as a negative feedback signal to the base of the phototransistor Q10 according to the flowing current. As a result, a collector current flows from the COMP terminal of the switching control circuit Q12 toward the phototransistor Q10. This collector current is a current value corresponding to the current flowing through the LED Q19 (the larger the current flowing through the LED Q19, the larger the current). The switching control circuit Q12 determines whether or not to switch the MOSFETs Q8 and Q9 based on the collector current value. That is, when this collector current is large (that is, the voltage of the secondary winding of the transformer T is large), the MOSFETs Q8 and Q9 stop switching operations (both are turned off), and the collector current is small (that is, the two of the transformer T When the voltage of the next winding is small), the MOSFETs Q8 and Q9 are caused to perform switching operations. Therefore, negative feedback is executed, the switching operation is executed intermittently, the voltage of the secondary winding of the transformer T is kept at the minimum necessary voltage, and wasteful power consumption can be reduced.

  As described above, by switching the signal supplied to the node X9 of the feedback control unit 2A between the high level and the low level, the state where the current flows through the LED Q19 and the state where it does not flow are switched. As a result, it is possible to switch between a state in which a feedback signal is supplied to the switching control circuit Q12 and a state in which no feedback signal is supplied.

  The effects of the switching power supply 2 will be described. In the normal operation state, the negative feedback signal is not supplied to the switching control circuit Q12, and the MOSFETs Q8 and Q9 always perform the switching operation, so that the sound quality of the audio signal output from the switching amplifier 1 can be improved. On the other hand, in the standby state, a negative feedback signal is supplied to the switching control circuit Q12, and the MOSFETs Q8 and Q9 perform the switching operation intermittently, so that the output power supply voltage can be suppressed to the minimum, and the power consumption can be reduced. Can be reduced. Conventionally, the power supply voltage has been switched by providing a power supply circuit for a normal operation state and a power supply circuit for a standby, but a power supply circuit for a normal operation state and a power supply circuit for a standby are switched by one switching power supply. And the power circuit can be reduced in size and the number of parts can be reduced.

[Control circuit 3]
FIG. 4 is a circuit diagram showing a configuration of the control circuit 3. The control circuit 3 controls on / off of the transistors Q4, Q6, and Q13 of the power control units 1A, 1B, and 1C of the switching amplifier 1, and controls the supply / non-supply of each power supply voltage to the driver Q1. Further, the control circuit 3 controls on / off of the transistor Q17 of the feedback control unit 2A of the switching power supply 2 to control whether or not a negative feedback signal is supplied to the switching control circuit Q12, and the switching power supply 2 is in a normal operation state, or , Switch to standby mode. Further, the control circuit 3 outputs a stop control signal for stopping the operation of the driver Q1 to the driver Q1 for a predetermined time after which the operation of the driver Q1 is stabilized after the input signal is started to be supplied.

  The control circuit 3 schematically includes transistors Q20 to Q44, resistors R28 to R58, capacitors C15 to C27, and a photocoupler (LED Q30, phototransistor Q11 (see FIG. 3)). Below, the connection relationship of the principal part of the control circuit 3 is demonstrated.

  The transistor Q21 has a base connected to the cathodes of the diodes D18 and D19, an emitter connected to the ground potential, and a collector connected to the base of the transistor Q22. The transistor Q22 has an input signal supplied to the base, an emitter connected to the ground potential, and a collector connected to the base of the transistor Q23. The transistor Q23 has a collector connected to the emitter of the transistor Q24 and the bases of the transistors Q32 and Q33, and an emitter connected to the power supply voltage line. The base of the transistor Q24 is connected to the ground potential via the resistor R32, the collector is connected to the node X2 via the diode D13 and the resistor R34, and the node is connected to the node X3 via the diode D14 and the resistor R35. .

  Transistor Q25 has a base connected to the collector of transistor Q23 via capacitor C16 and resistor R33, an emitter connected to the ground potential, a collector connected to the base of transistor Q27 via resistor R36, and a resistor It is connected to the base of the transistor Q28 via R39 and the diode D17. The Zener diode D15 has a cathode connected to the connection point between the resistor R33 and the capacitor C16, and an anode connected to the ground potential. The base of the transistor Q26 is connected to the base of the transistor Q36, the collector of the transistor Q37, and the collector of the transistor Q38 via a resistor R49. Transistor Q27 has an emitter connected to the power supply voltage line and a collector connected to the base of transistor Q42 via resistor R37.

  Transistor Q28 has a base connected to the power supply voltage line via capacitor C18, an emitter connected to the power supply voltage line, a collector connected to the base of transistor Q29, a ground potential via resistor R40, and capacitor C19. ing. The transistor Q29 has a collector connected to the base of the transistor Q21 via the diode D18, is connected to the anode of the LED Q30 via the resistor R41, and an emitter is connected to the capacitor C19 and the collector of the transistor Q44. The cathode of the LED Q30 is connected to the ground potential. Transistor Q32 has an emitter connected to the ground potential and a collector connected to node X1. The node X1 is connected to the node X1 in FIG.

  Transistor Q42 has an emitter connected to the ground potential and a collector connected to node X8. The node X8 is connected to the node X8 in FIG. 2, that is, connected to the RESET input terminal of the driver Q1. Transistor Q43 has a base connected to node X8 via resistor R58, a collector connected to the ground potential, and an emitter connected to the base of transistor Q44 via resistor R57. The emitter of the transistor Q44 is connected to the power supply voltage line.

The operation will be described below. 5 to 7 are timing charts showing the operation of each part of the control circuit 3, and each symbol corresponds to an operation waveform or the like of each part of the control circuit 3.
[When input signal (audio signal) starts input in standby mode]
This will be described with reference to the timing chart of FIG. When the input signal starts to be input at time t1 ((1) in FIG. 5, time t1), the input signal is rectified and smoothed by a rectifying and smoothing circuit (not shown), and a positive voltage is supplied to the base of the transistor Q22. Transistor Q22 is turned on. When the transistor Q22 is turned on, the base of the transistor Q23 is connected to the ground potential, and the transistor Q23 is turned on ((2) in FIG. 5, time t1). That is, an input signal is detected. When the transistor Q23 is turned on, the control circuit 3 starts the supply of the power supply voltage to the driver Q1 of the switching amplifier 1 and controls the switching control circuit 12 not to supply the negative feedback signal.

  Specifically, the high level of the emitter of the transistor Q23 is output to the node X9 via the diode D12 ((3) in FIG. 5, time t1). Since the node X9 is connected to the node X9 in FIG. 3, a high-level signal is supplied to the base of the transistor Q17 of the feedback control unit 2A to control the transistor Q17 to be in an on state. As described above, by controlling the transistor Q17 to the on state, the negative feedback signal is not supplied to the switching control circuit Q12, and the switching power supply circuit 2 always performs the switching operation and shifts from the standby state to the power on state. .

  Since the high level of the emitter of the transistor Q23 is supplied to the emitter of the transistor Q24, the transistor Q24 is turned on. When the transistor Q24 is turned on, a high level signal is output to the node X2 via the diode D13 and the resistor R34. The node X2 is connected to the node X2 in FIG. Therefore, a high level signal is supplied to the base of the transistor Q6 of the power supply control unit 1B of the switching amplifier 1, and the transistor Q6 can be controlled to be in an on state. As described above, when the transistor Q6 is turned on, the power supply voltage VSS is input to the power supply input terminal VSS of the driver Q1.

  Further, when the transistor Q24 is turned on, a high level signal is output to the node X3 via the diode D14 and the resistor R35. The node X3 is connected to the node X3 in FIG. Therefore, a high level signal is supplied to the base of the transistor Q14 of the power supply control unit 1C of the switching amplifier 1, and the transistor Q14 is turned on. The base of the transistor Q13 is turned on with the base connected to the ground potential. As described above, when the transistor Q13 is turned on, the power supply voltage VB is input to the power supply input terminal VCC of the driver Q1.

  Since the high level of the emitter of the transistor Q23 is supplied to the base of the transistor Q32, the transistor Q32 is turned on. When the transistor Q32 is turned on, a low level signal (ground potential) is output to the node X1. The node X1 is connected to the node X1 in FIG. Therefore, a low-level signal is supplied to the base of the transistor Q4 of the power supply control unit 1A of the switching amplifier 1, and the transistor Q4 can be controlled to be in an on state. As described above, when the transistor Q4 is turned on, the power supply voltage VAA is input to the power supply input terminal VAA of the driver Q1.

  As described above, when the input signal is started, by turning on the transistor Q23, the transistors of the power supply control units 1A to 1C can be controlled to be turned on, and the power supply voltages VAA, VSS, VCC are supplied to the driver Q1. Supply can be started.

  Here, the driver Q1 of the switching amplifier 1 needs to be controlled not to output a drive signal until the stable operation can be performed after the supply voltages VAA, VSS, and VB are started. . The driver Q1 has a RESET terminal. This is because outputting a drive signal until stable operation can be performed may cause noise or damage to the MOSFET. For example, when a low level signal is supplied to the RESET terminal, the driver Q1 stops outputting the drive signals DRV1 and DRV2.

  The high level of the emitter of the transistor Q23 is made constant by the Zener diode D15 via the resistor R33, and the capacitor 16 is instantaneously charged. The base of the transistor Q25 is supplied with a high-level signal that is the charging voltage of the capacitor C16, and is turned on. When the transistor Q25 is turned on, a low level signal (ground potential) of the emitter of the transistor Q25 is supplied to the base of the transistor Q27 via the resistor R36, and the transistor Q27 is turned on ((4) in FIG. 5). Time t1). A high level signal from the emitter of the transistor Q27 is supplied to the base of the transistor Q42 via the resistor R37, and the transistor Q42 is turned on. A low level signal (ground potential) of the emitter of the transistor Q42 is output to the node X8 ((5) in FIG. 5, time t1). The node X8 is connected to the node X8 in FIG. Accordingly, a low level signal is input to the RESET terminal of the driver Q1 of the switching amplifier 1, and the driver Q1 stops outputting the drive signal.

  After the transistor Q25 is turned on, the charging voltage of the capacitor C16 is gradually discharged to the ground potential via the internal resistance of the transistor Q25. This discharge time depends on the time constant between the capacitor C16 and the internal resistance of the transistor Q25. When the charging voltage of the capacitor C16 decreases after the predetermined time has elapsed, the transistor Q25 is turned off. Then, the transistors Q27 and Q42 are turned off by an operation reverse to the above ((4) in FIG. 5, time t3). Therefore, the low level signal is not input to the RESET terminal of the driver Q1, and the driver Q1 can start outputting the drive signal ((10) in FIG. 5, time t3). Thus, the time from when the transistor Q25 is turned on to when it is turned off, that is, the time until the charging voltage of the capacitor C16 is discharged according to the time constant between the capacitor C16 and the internal resistance of the transistor Q25, This corresponds to the time during which the output of the drive signal is stopped until the driver Q1 can start the stable operation.

  Further, when the transistor Q25 is turned on, a low level signal (ground potential) of the emitter of the transistor Q25 is supplied to the base of the transistor Q28 via the resistor R39 and the diode D17, and the transistor Q28 is turned on. When the transistor Q28 is turned on, a high level signal from the emitter of the transistor Q28 is supplied to the base of the transistor Q29, and the transistor Q29 is turned off ((6) in FIG. 5, time t1). Here, when the node X8 becomes low level as described above, a low level signal is supplied to the base of the transistor Q43, and the transistor Q43 is turned on. Then, a low level signal (ground potential) at the collector of the transistor Q43 is supplied to the base of the transistor Q44, and the transistor Q44 is turned on. Then, a high level signal from the emitter of the transistor Q44 is supplied to the emitter of the transistor Q29.

  If the transistor Q29 is turned on, a high level signal is supplied to the anode of the LED Q30, a current flows through the LED Q30, the phototransistor Q11 is turned on, and the 5V voltage at the VREF terminal of the switching control circuit Q12 is STOP. As a result, the switching control circuit Q12 stops operating. The reason why such a problem occurs is that the node X8 is also a node to which a low level signal for protection described later is supplied. However, by turning off the transistor Q29, it is possible to prevent a current from flowing through the LED Q30, and it is possible to prevent the switching control circuit Q12 from stopping its operation. Note that after the transistor Q25 is turned off, there is a period in which a current flows from the emitter of the transistor Q28 to the capacitor C18 to charge the capacitor C18, and during this period, the transistor Q28 continues to be on (FIG. 5 ( 6) until time t4). When the capacitor C18 is fully charged and no current flows from the emitter of the transistor Q28 to the capacitor C18, the transistor Q28 is turned off. Accordingly, it is possible to prevent the operation of the switching control circuit Q12 from being erroneously stopped by keeping the transistor Q29 in the off state for a predetermined period after the transistor Q25 is in the off state.

[When input signal (audio signal) stops being input]
Contrary to the previous case, when the input signal is not input ((1) in FIG. 5, time t5), after a predetermined time has elapsed due to the time constants of the resistor R100 and the capacitor C100 in FIG. The voltage is not supplied, the transistor Q22 is turned off, and the transistor Q23 is turned off ((2) in FIG. 5, time t6). When the transistor Q23 is turned off, the control circuit 3 stops the supply of the power supply voltage to the driver Q1 of the switching amplifier 1, supplies a negative feedback signal to the switching control circuit 12, and controls to shift to the standby state. To do.

  Specifically, when the transistor Q23 is turned off, the anode of the diode D12 is connected to a low level (ground potential) and turned off. Therefore, a high level signal is not supplied to the base of the transistor Q17 of the feedback control unit 2A in FIG. 3, and the transistor Q17 is turned off. As described above, when the transistor Q17 is turned off, a negative feedback signal is supplied to the switching control circuit Q12, and the switching power supply circuit 2 shifts from the normal operation state to the standby state.

  Since the transistor Q24 is turned off, a high level signal is not supplied to the base of the transistor Q6 of the power supply controller 1B of the switching amplifier 1, and the transistor Q6 is turned off. As described above, when the transistor Q6 is turned off, the power supply voltage VSS is not input to the power supply input terminal VSS of the driver Q1.

  When the transistor Q24 is turned off, a high level signal is not supplied to the base of the transistor Q14 of the power supply controller 1C of the switching amplifier 1, and the transistor Q14 is turned off. The base of the transistor Q13 is not connected to the ground potential and is turned off. As described above, when the transistor Q13 is turned off, the power supply voltage VB is not input to the power input terminal VCC of the driver Q1.

  When the transistor Q23 is turned off, the transistor Q32 is turned off, a low level signal is not supplied to the base of the transistor Q4 of the power supply control unit 1A of the switching amplifier 1, and the transistor Q4 is turned off. As described above, when the transistor Q4 is turned off, the power supply voltage VAA is not input to the power input terminal VAA of the driver Q1.

  Thus, when the input signal is not input, the transistor Q23 is turned off, so that the transistors of the power control units 1A to 1C can be controlled to be turned off, and the power supply voltages VAA, VSS, and VB are supplied to the driver Q1. Supply can be stopped. Therefore, the operation of the switching amplifier 1 can be stopped ((10) in FIG. 5, time t6).

[Protect operation]
This will be described with reference to the timing chart of FIG. A protect signal (low level signal) is supplied to the node X8 ((5) in FIG. 6, time t11). The protect signal is supplied to the node X8 when the temperature detection unit 3A in FIG. In addition, although not shown in the figure, it is detected whether or not the output signal of the MOSFETs Q2 and Q3 of the switching amplifier 1 includes DC (direct current component), and if it is included, the protect signal is supplied to the node X8. . Further, it is detected whether a pumping phenomenon has occurred in the power supply voltages + B, -B, which are the outputs of the full-wave rectifier circuit D6 of the switching power supply 2, and when it occurs, a protect signal is supplied to the node X8. Since these detection circuits themselves are well-known techniques, detailed description thereof is omitted.

  The protect signal (low level signal) supplied to the node X8 is input to the RESET terminal of the driver Q1. Therefore, the driver Q1 can stop outputting the drive signal. The protect signal (low level signal) supplied to the node X8 is supplied to the base of the transistor Q43, and the transistor Q43 is turned on. A low level signal (ground potential) at the collector of the transistor Q43 is supplied to the base of the transistor Q44, and the transistor Q44 is turned on. A high level signal from the emitter of the transistor Q44 is supplied to the emitter of the transistor Q29. Since the base of the transistor Q29 is connected to the ground potential, the transistor Q29 is turned on.

  Therefore, the high level of the emitter of the transistor Q29 is supplied to the anode of the LED Q30 via the resistor R41, a current flows through the LED Q30, and the phototransistor Q11 is turned on. Then, since the VREF terminal of the switching control circuit Q12 outputs a 5V voltage, the 5V voltage is input to the STOP terminal. That is, a current flows from the VREF terminal to the STOP terminal via the phototransistor Q11. When the input voltage at the STOP terminal exceeds 4.5 V (when such a current flows), the switching control circuit Q12 stops its operation and always outputs a low level signal from the control terminal HVG and the control terminal LVG. The on / off operation of the MOSFETs Q8 and Q9 is stopped. Therefore, the operation of the switching power supply 2 can be stopped ((7) in FIG. 6, time t11).

  Further, the high level signal of the emitter of the transistor Q29 is supplied to the base of the transistor Q21 via the diode D18, and the transistor Q21 is turned on. A low level signal (ground potential) of the emitter of the transistor Q21 is supplied to the base of the transistor Q22, and the transistor Q22 is turned off. Accordingly, the transistor Q23 is also turned off, and as a result, the supply of the power supply voltage to the driver Q1 of the switching amplifier 1 is stopped and the negative feedback signal is not supplied to the switching control circuit Q12, as in the case where the input signal is not supplied. To control.

  That is, when the transistor Q23 is turned off, the anode of the diode D12 is connected to the low level (ground potential) and turned off. Therefore, a high level signal is not supplied to the base of the transistor Q17 of the feedback control unit 2A in FIG. 3, and the transistor Q17 is turned off. As described above, when the transistor Q17 is turned off, a negative feedback signal is supplied to the switching control circuit Q12.

  Since the transistor Q24 is turned off, the diode D13 is turned off, and a high-level signal is not supplied to the base of the transistor Q6 of the power supply controller 1B of the switching amplifier 1, so that the transistor Q6 is turned off. As described above, when the transistor Q6 is turned off, the power supply voltage VSS is not input to the power supply input terminal VSS of the driver Q1.

  Further, when the transistor Q24 is turned off, the diode D14 is turned off, a high level signal is not supplied to the base of the transistor Q14 of the power supply control unit 1C of the switching amplifier 1, and the transistor Q14 is turned off. The base of the transistor Q13 is not connected to the ground potential and is turned off. As described above, when the transistor Q13 is turned on, the power supply voltage VB is not input to the power input terminal VCC of the driver Q1.

  When the transistor Q23 is turned off, the transistor Q32 is turned off, a low level signal is not supplied to the base of the transistor Q4 of the power supply control unit 1A of the switching amplifier 1, and the transistor Q4 is turned off. As described above, when the transistor Q4 is turned off, the power supply voltage VAA is not input to the power input terminal VAA of the driver Q1.

[Low voltage detector]
As shown in FIGS. 3 and 4, the control circuit 3 includes a low voltage detection unit 3B. The low voltage detector 3B includes resistors R14, R15, R16, R17, R18, Zener diodes D9, D20, a capacitor C2, transistors Q16, Q26, Q35, Q36, Q37, Q38, Q39. The low voltage detection unit detects that the voltage induced in the secondary winding of the transformer T is a low voltage, and when the low voltage is detected, the feedback control unit 2A is fed back to the switching control circuit Q12. Control is performed so that no signal is supplied, and the switching power supply 2 is maintained in a normal operation state.

  The base of the transistor Q16 is connected to the cathode of the diode D7 via the parallel circuit of the resistors R15 and R16 and the Zener diode D9, the emitter is connected to the node X5, and the collector is connected to the node X7 via the resistor R18. The transistor Q39 is connected to the base. The base of the transistor Q37 is connected to the collector of the transistor Q35 via the resistor R47, the emitter is connected to the power supply voltage line, and the collector is connected to the collector of the transistor Q38 and the anode of the diode D20 via the resistor R49. . Transistor Q38 has an emitter connected to the ground potential, a base connected to the collector of transistor Q39, and a capacitor C2 connected to the ground potential. The transistor Q39 has an emitter connected to the power supply voltage line. The cathode of the diode D20 is connected to the node X9. The node X9 is connected to the node 9 of FIG. 3, that is, the base of the transistor Q17. The base of the transistor Q35 is connected to the collector of the transistor Q23 via the resistor R43, and the emitter is connected to the ground potential.

[Operation when detecting low voltage]
This will be described with reference to t21 to t22 in the timing chart of FIG. When the voltage of the secondary winding of the transformer T becomes low, a low level signal is supplied to the base of the transistor Q16, so that the transistor Q16 is turned off (low voltage is detected). The low level signal (ground potential) of the emitter of the transistor Q16 is not supplied to the base of the transistor Q39, and the transistor Q39 is turned off ((8) in FIG. 7, time t21). The high level signal is not supplied to the base of the transistor Q38, and the transistor Q38 is turned off. Here, when an input signal is input and the transistor Q23 is in an on state, a high level signal is supplied to the base of the transistor Q35, and the transistor Q35 is in an on state. Therefore, the transistor Q37 is turned on because the low level signal (ground potential) is supplied to the base ((9) in FIG. 7, time t21).

  Since the transistor Q37 is turned on and Q38 is turned off, a high level signal of the emitter of the transistor Q37 is output to the node X9 via the resistor R49 and the diode D20 ((3) in FIG. 7, time t21). As shown in FIG. 3, since the node X9 is connected to the base of the transistor Q17, a high level signal is supplied to the base and the transistor Q17 continues to be in the on state. As described above, when the transistor Q17 is turned on, the negative feedback signal is not supplied to the switching control circuit Q12, and the switching power supply maintains the normal operation state. As will be described later, when a low voltage is detected, the transistor Q23 is turned off and the diode D12 is turned off, so that a low level signal is output from the node X9 (transition to the standby state). However, since the high level signal from the diode D20 is output to the node X9, it is possible to prevent the transition to the standby state.

  When transistor Q37 is turned on and Q38 is turned off, a high level signal from the emitter of transistor Q37 is supplied to the base of transistor Q21 via resistor R49 and diode D19, and transistor Q21 is turned on. A low level signal (ground potential) of the emitter of the transistor Q21 is supplied to the base of the transistor Q22, and the transistor Q22 is turned off. Accordingly, the transistor Q23 is also turned off, and as a result, the supply of the power supply voltage to the driver Q1 of the switching amplifier 1 is stopped as in the case where the input signal is not supplied.

  More specifically, since the transistor Q24 is turned off when the transistor Q23 is turned off, the diode D13 is turned off, and a high-level signal is supplied to the base of the transistor Q6 of the power supply control unit 1B of the switching amplifier 1. The transistor Q6 is turned off. As described above, when the transistor Q6 is turned off, the power supply voltage VSS is not input to the power supply input terminal VSS of the driver Q1.

  Further, when the transistor Q24 is turned off, the diode D14 is turned off, a high level signal is not supplied to the base of the transistor Q14 of the power supply control unit 1C of the switching amplifier 1, and the transistor Q14 is turned off. The base of the transistor Q13 is not connected to the ground potential and is turned off. As described above, when the transistor Q13 is turned on, the power supply voltage VB is not input to the power input terminal VCC of the driver Q1.

  When the transistor Q23 is turned off, the transistor Q32 is turned off, a low level signal is not supplied to the base of the transistor Q4 of the power supply control unit 1A of the switching amplifier 1, and the transistor Q4 is turned off. As described above, when the transistor Q4 is turned off, the power supply voltage VAA is not input to the power input terminal VAA of the driver Q1.

  The high level signal of the emitter of the transistor Q37 is supplied to the base of the transistor Q26 via the resistor R49, and the transistor Q26 is turned on. A low level signal (ground potential) is supplied to the base of the transistor Q27, and the transistor Q27 is turned on. A high level signal is supplied to the base of the transistor Q42, and the transistor Q42 is turned on. Therefore, a low level signal is output from the node X8 and input to the RESET terminal of the driver Q1 of the switching amplifier 2 in FIG. 2, and the drive signal output of the driver Q1 can be stopped ((4) in FIG. t21). That is, as described above, the transistors Q4, Q6, and Q13 are controlled to be in the OFF state, and supply of the power supply voltage to the driver Q1 is stopped. However, since a slight time lag is assumed, a low level is applied to the RESET terminal of the driver Q1. By supplying the signal, the drive signal output operation of the driver Q1 can be quickly stopped.

  When the transistor Q26 is turned on, a low level signal (ground potential) is supplied to the base of the transistor Q28, and the transistor Q28 is turned on. A high level signal is supplied to the base of the transistor Q29 and the transistor Q29 is turned off ((6) in FIG. 7, time t21). If the transistor Q29 is turned on, a high level signal is supplied to the anode of the LED Q30, a current flows through the LED Q30, the phototransistor Q11 is turned on, and the 5V voltage at the VREF terminal of the switching control circuit Q12 is STOP. As a result, the switching control circuit Q12 stops operating. The reason why such a problem occurs is that the node X8 is also a node to which a low level signal for protection is supplied. However, by turning off the transistor Q29, it is possible to prevent a current from flowing through the LED Q30, and it is possible to prevent the switching control circuit Q12 from stopping its operation.

  Note that when the transistor Q23 is turned off, the transistor Q35 is turned off, so that the transistor Q37 cannot be kept on. When the transistor Q37 is turned off, the operation at the time of detecting the low voltage described above cannot be executed. However, once the transistor Q37 is turned on, the high level of the emitter of the transistor Q37 is supplied to the base of the transistor Q36, and the transistor Q36 is turned on. Since a low level signal is supplied to the base of the transistor Q37, the transistor Q37 can be kept on ((9) in FIG. 7, time t21).

  The effect of the low voltage detection part 3B is demonstrated. First, when the switching power supply is in a standby state, the following problem occurs. If the switching power supply 2 is in a standby state when the power supply voltage becomes low, the charging voltage of the smoothing capacitors C101 and C102 is not immediately used for output of the power supply voltage in the switching power supply 2, and the comparison is made. A long period remains. When a low voltage is detected and the operation of the driver Q1 of the switching amplifier 1 is stopped, the load becomes lighter, so that the voltage supplied to the base of the transistor Q16 rises and the transistor Q16 is turned on. End up. That is, even though the voltage is low, it is determined that the voltage is not low. Therefore, the operation of the driver Q1 of the switching amplifier 1 is started. Then, the load becomes heavy, the voltage supplied to the base of the transistor Q16 is reduced, and the transistor Q16 is turned off. In this way, until the charging voltage of the capacitors C101 and C102 is completely consumed, the process of detecting the low voltage and stopping the operation of the switching amplifier, and starting the operation of the switching amplifier without detecting the low voltage. There is a problem that the processing is repeated over a long period of time, and as a result, noise is generated from the speaker.

  In the low voltage detection unit 3B of this example, as described above, when a low voltage is detected, the supply of the negative feedback signal to the switching control circuit Q12 of the switching power supply 2 is stopped and the transition to the standby state is prevented. Continue normal operation. Therefore, the charging voltages of the capacitors C101 and C102 are used and consumed quickly for generating the power supply voltage in the normal operation state. Therefore, it is possible to finish in a short time the time for repeating the process of detecting the low voltage and stopping the operation of the switching amplifier and the process of starting the operation of the switching amplifier without detecting the low voltage.

  As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to these embodiment.

  The present invention can be suitably employed for an audio amplifier, for example.

1 switching amplifier 2 switching power supply 3 control circuit

Claims (3)

The switching amplifier included in the audio device is controlled to operate or stop in conjunction with the normal operation state and the standby state of the audio device, and the switching is performed in conjunction with the normal operation state and the standby state of the audio device. A control circuit that controls the power supply to a normal operation state or a standby state ,
The switching power supply is
A switching element that is supplied with a power supply voltage and performs a switching operation in response to a control signal from the switching control unit;
The switching control unit for supplying a control signal for switching the switch element to the switch element;
In the normal operation state of the switching power supply, no feedback signal is supplied to the switching control unit, and in the standby state of the switching power supply, a feedback signal corresponding to the output voltage from the switch element is supplied to the switching control unit. And a feedback control unit that
The switching control unit always switches the switching element when the feedback signal is not supplied, and intermittently switches the switching element according to the feedback signal when the feedback signal is supplied. Yes,
The control circuit comprises:
A low voltage detection unit for detecting that the output voltage of the switching power supply is a low voltage;
In the normal operation state of the audio device, when it is detected that the output voltage of the switching power supply is a low voltage, the feedback control unit is controlled not to supply a feedback signal to the switching control unit, and the switching power supply A control unit for maintaining a normal operation state;
When the output voltage of the switching power supply is detected to be low in the normal operation state of the audio apparatus, a stop control signal for stopping the drive signal output operation of the driver of the switching amplifier is output from the first node. A stop control signal output unit,
A control circuit comprising: A regulator element for generating a current corresponding to an output voltage from the switch element;
A light emitting element that receives an electric current flowing through the regulator element and outputs an optical signal as the feedback signal;
A light receiving element that receives an optical signal from the light emitting element and flows a current as the feedback signal to the switching control unit;
A state switch element for switching whether or not to pass a current to the regulator element;
2. The control circuit according to claim 1, wherein when the control unit detects that the output voltage of the switching power supply is a low voltage, the control unit controls the state switch element so that no current flows through the regulator element. 3. . When protect signal for stopping the operation of the switching control unit of the switching power supply before Symbol first node is supplied, a current flows in response to the protection signal, and a second light emitting element that outputs an optical signal,
A second light receiving element that stops the operation of the switching control unit in response to an optical signal from the second light emitting element;
When it is detected that the output voltage of the switching power supply is a low voltage, the switching power supply is turned off, the path of the current flowing through the second light emitting element is opened, and no current flows through the second light emitting element. The control circuit according to claim 1, further comprising: a transistor that controls as described above.

Images